Monolithic programmable attenuator

ABSTRACT

A programmable attenuator includes a plurality of field effect transistors (FETS) arranged together to provide an attenuation network. Each one of the FETS has a plurality of cell portions, each cell portion having drain, gate and source regions, the source and drain regions of the cell portions being connected in parallel. A first selected portion of the gate regions of each one of said FETS is connected to a gate electrode. A second selected remaining portion of the gate regions of each one of the FETS has the gate regions thereof physically isolated from the gate electrode. A signal fed to the gate electrode of each FET is distributed to the connected gate regions of each field effect transistor. In response to such signal, the total drain-source resistance of such FET is changed between a predetermined low value and a predetermined high value, with the resistance of the predetermined high value being determined, in part, by the number of such isolated gate regions.

This application is a divisional application of Ser. No. 810,900 filed on Dec. 20, 1985 now U.S. Pat. No. 4,684,965 which is a continuation of Ser. No. 492,857 filed on May 9, 1983 now abandoned.

BACKGROUND OF THE INVENTION

This invention relates generally to radio frequency circuits and more particularly to radio frequency circuits for selectively attenuating a signal fed thereto.

As is known in the art, attenuators are used for a variety of applications, for automatic gain control circuits, and in particular, in broadband temperature compensated microwave amplifiers for temperature compensation of gain over an operating range of temperatures. One type of attenuator often used is a programmable attenuator. A programmable attenuator provides a selected predetermined fixed attenuation in response to a set of signals fed thereto. A general technique for providing a programmable attenuator, such as those described in U.S. Pat. No. 3,765,020 and U.S. Pat. No. 4,121,183, employs field effect transistors to selectively switch passive elements such as resistors to provide a properly configured attenuation network to thereby provide, in response to a signal fed to such network, a predetermined attenuated output signal. While these attenuators are useful in certain applications, one problem associated with these types of attenuators is that such circuits are not particularly well suited for fabrication on a common substrate such as by using monolithic microwave integrated circuit techniques since a resistor ladder network is required to provide attenuation, and an impedance matching network is required for matching the attenuator to external circuits.

SUMMARY OF THE INVENTION

In accordance with the present invention, a programmable attenuator includes a plurality of field effect transistor cells interconnected to provide an attenuation network. Each one of the field effect transistors has a plurality of cell portions, each cell portion having drain, gate and source regions, the source and drain regions of the cell portions being connected in parallel. A first selected portion of the gate regions of each one of said FETS is connected to a gate electrode. A second selected remaining portion of the gate regions of each one of the FET cells has the gate regions thereof physically isolated from the gate electrode. A signal fed to the gate electrode of each FET is distributed to the connected gate regions of each FET. In response to such signal, the total resistance of a drain-source channel of each FET is changed between a predetermined low resistance value and a predetermined high resistance value with the predetermined high resistance value being determined in part by the number of such isolated gate regions. With such an arrangement, by selecting values of channel resistance for the FET in the high state and the low state, an attenuation network may be provided to have a constant characteristic impedance related to the characteristic impedance of an input circuit connected thereto. Further, such a circuit can be easily fabricated on a common substrate using monolithic microwave integrated circuit techniques.

BRIEF DESCRIPTION OF THE DRAWINGS

The foregoing features of this invention, as well as the invention itself, may be more fully understood from the following detailed description read together with the accompanying drawings, in which:

FIG. 1 is a schematic representation of an attenuator in accordance with the invention;

FIG. 2 is an equivalent circuit of the attenuator of FIG. 1;

FIG. 2A is a simplified equivalent circuit of the attenuator of FIG. 2 showing a conventional T network for use in deriving certain equations useful in understanding the present invention;

FIG. 3 is a plan view of the attenuator shown in FIG. 1 fabricated as a monolithic integrated circuit;

FIG. 4 is an exploded plan view of a transistor used in the attenuator of FIG. 3;

FIG. 4A is a cross-sectional view of the transistor shown in FIG. 4 taken along line 4A--4A; and

FIG. 5 is an exploded plan view of a dual gate transistor used in the attenuator of FIG. 3.

DESCRIPTION OF THE PREFERRED EMBODIMENT

Referring now to FIG. 1, an r.f. energy source 20 is shown connected, via a radio frequency transmission line 19a to a 1-bit two state digital attenuator 10. The digital attenuator 10 is shown to include a plurality of field effect transistors, here 14a, 14b, 14c, each one of such field effect transistors having gate electrodes 15a, 15b, 15c, drain electrodes 16a, 16b, 16c and source electrodes 17a, 17b and 17c, respectively. Two of such field effect transistors (FET) here FETS 14a, 14b are connected in series with the input radio frequency transmission line 19a, and an output radio frequency (r.f.) transmission line 19d with the drain electrode 16a of FET 14a being connected to the r.f. transmission line 19a, source electrode 17a thereof being connected via transmission lines 19b, 19c to the drain electrode 16b of FET 14b and source electrode 17b being connected to the output transmission line 19d. Output r.f. transmission line 19d is connected to a load 22. Load 22 here has a characteristic impedance (Z_(o)) equal to 50 ohms. The third field effect transistor 14c connected in shunt between the interconnection of FETS 14a, 14b and ground, has drain electrode 16c connected at the interconnection of transmission lines 19b and 19c, and has source electrode 17c connected to ground, as shown.

Gate bias for gate electrodes 15a, 15b of field effect transistors 14a, 14b is provided at a bias terminal V₁. The gate bias circuit includes a decoupling capacitor 12a connected in shunt between terminal V₁ and ground, a first length of transmission line 13a connected between bias point V₁ and one end of a resistor R_(a) with a second end of resistor R_(a) being connected to gate electrode 15a of field effect transistor 14a, and a second, here equal length of transmission line 13b connected between bias point V₁ and a first end of a resistor R_(b), the second end of resistor R_(b) being connected to the gate electrode 15b of field effect transistor 14b. In a similar manner, the gate bias circuit for field effect transistor 14c includes a bypass capacitor 12b connected in shunt between ground and a bias point V₂ and a length of transmission line 13c connected between bias point V₂ and gate electrode 15c, and with resistor R_(c) being connected to the gate electrode 15c and field effect transistor 14c.

By feeding voltage signals from a bias control means 21 to terminal V₁ and to terminal V₂, the equivalent values of channel resistance of each FET 14a-14c here represented as resistors R₁, R₂, R₃ (FIG. 2A) will change between values of resistance R_(1L), R_(1H) and R_(2L), R_(2H) and R_(3L), R_(3H), respectively, in accordance with the value of the voltage level signal fed thereto. FET's 14a-14c are here depletion mode metal electrode semiconductor field effect transistors (MESFET's). Typically, a voltage level signal of zero volts with respect to the source electrode is applied to the gate electrode of such an FET to select a low value of channel resistance (R_(1L), R_(2L), R_(3L)) (FIG. 2) and a value of voltage corresponding to the pinch-off voltage, typically -5V is applied to the gate electrode to select a high value of channel resistance R_(1H), R_(2H), R_(3H) (FIG. 2). Resistors R_(a), R_(b), R_(c) are used to limit drain-gate current under a strong r.f. drive and also increases isolation between drain and gate electrodes. There is no drain bias circuit for attenuator 10 since FET's 14a-14b are here operated as variable resistors and as such passive operation does not require the use of a drain bias.

Referring now to FIG. 2, an equivalent circuit 10' for the attenuator 10 (FIG. 1) is shown to include a first parallel combination of resistors R_(1L) and R_(1H) and a switch S₁ which selects a path between input transmission line 19a, and the switch S₁ through one of such resistors R_(1L), R_(1H). The parallel combination of R_(1L), R_(1H), and the switch S₁ here represents the equivalent circuit of FET 14a and is connected in series with a switch S₂ which selects a path between the switch S₂ and one resistor of a second parallel combination of resistors R_(2L) and R_(2H). The switch S₂ and the parallel combination of resistors R_(2L), R_(2H) here represents the equivalent circuit of FET 14b. In a preferred embodiment of the invention, R_(1L) =R_(2L) and R_(1H) =R_(2H). A third parallel combination of resistors R_(3L) and R_(3H) and a series connected switch S₃ here representing FET 14c is coupled in shunt with the interconnection of the switches S₁ and S₂, as shown. Resistors R_(1L), R_(2L), R_(3L) here represent the value of the low state or unpinched channel resistance of the corresponding FETS 14a-14c (FIG. 1), whereas, resistors R_(1H), R_(2H), R_(3H) here represent the value of pinched-off or high state value of channel resistance for FETS 14a-14c in accordance with the invention, and switches S₁ -S₃ here represent the switch states of the FETS 14a-14c, respectively. In response to control signals from bias control means 21 (FIG. 1) fed to gate electrodes 15a-15c of FETS 14a-14c (FIG. 1), the value of channel resistance of each FET 14a-14c is selectively changed between the high state and the low state in accordance with the level of the signal. Therefore, as shown in FIG. 2, switches S₁ -S₃ here represent the switching action of the field effect transistors 14a-14c, changing the value of channel resistance between R_(1L) -R_(3L) and R_(1H) -R_(3H), in accordance with the voltage level of such control signals. In a preferred embodiment of the invention, FETS 14a, 14b and 14c are designed to provide values of resistance in the pinched-off state and the on-state, so that the selected combination of such channel resistances will provide selected predetermined values of attenuation for the attenuator 10 (FIG. 1) and will provide values of input and output impedance substantially equal to a predetermined characteristic impedance value. Preferably, the input and output impedances of the attenuator 10 are equal to the characteristic impedances of the input and output r.f. transmission lines 19a, 19d, respectively. Suffice it here to say that each one of the values of channel resistance of each FET are selected to provide in combination such predetermined value of input impedance in a manner to be described.

Referring now to FIG. 2A, a simplified equivalent circuit of attenuator 10 (FIG. 1) is shown as a conventional T-section attenuator network 10" having branch resistor values R₁, R₂ and a shunt resistor R₃. It is to be noted that other attenuation networks such as a π-section network or a ladder network may also be used with the invention. Further, a multi-bit programmable attenuator having a plurality of FET's in each branch and shunt arm may be fabricated using the invention. Resistors R₁ -R₃ here represent channel resistances of FETS 14a-14c in each one of the selected states for such FETS 14a-14c. Here, in operation, the control signal is applied to the gate electrodes 15a, 15b of FETS 14a, 14b respectively and the complement of such signal is applied to the gate electrode 15c of FET 14c to switch said FETS in response to such signals to the selected channel resistance represented by resistor values R_(1L) or R_(1H), R_(2L) or R_(2H), and R_(3H) or R_(3L) in accordance with the voltage level of the signals applied to the gate electrodes 15a-15c. Resistance values R_(1L), R_(1H), R_(2L), R_(2H), R_(3L), R_(3H) are here selected such that any predetermined combination of such resistance values provides an input impedance Z_(in) of the attenuator 10, here preferably equal to Z_(o), the characteristic impedance of the radio frequency transmission lines 19a, 19d. With these constraints, the input impedance Z_(in) of the simplified equivalent circuit (FIG. 2A) is given as:

    Z.sub.in =(R.sub.1.sup.2 +2R.sub.1 R.sub.3).sup.1/2        Equation (1)

Further, since the network is symmetrical, the output impedance Z_(out) is likewise given by (R₂ ² +2 R₂ R₃)¹⁷⁸ where R₁ =R₂.

In a similar manner, a loop analysis of the simplified equivalent circuit of FIG. 2A will provide the following equation for the power attenuation factor for the condition Z_(in) =Z_(o) :

    A=P.sub.in /P.sub.o =(R.sub.1 +R.sub.3 +Z.sub.o /R.sub.3).sup.2 Equation (2)

Using the constraints that the input impedance equals the characteristic impedance, and the attenuation factor is related to the characteristic impedance, the values for resistors R₁, R₂ and R₃ can be shown to be equal to:

    R.sub.1 =Z.sub.o ((A).sup.1/2 -1)/((A).sup.1/2 +1) and     Equation (3)

    R.sub.3 =2 Z.sub.o (A).sup.1/2 /(A-1)                      Equation (4)

    R.sub.1 =R.sub.2 Equation (5)

                  TABLE 1                                                          ______________________________________                                         Z.sub.o = 50 ohms                                                              (values given are in ohms)                                                                                            Z.sub.o                                 A (Eq. 1)  R.sub.1 (Eq. 3)                                                                          R.sub.2 (Eq. 3)                                                                          R.sub.3 (Eq. 4)                                                                        (Eq. 2)                                 ______________________________________                                         RXL  2 db (1.58)                                                                               5.7 (R.sub.1L)                                                                           5.7 (R.sub.2L)                                                                         47 (R.sub.3H)                                                                         49.9                                  RXH  8 db (6.3)                                                                               21.5 (R.sub.1H)                                                                          21.5 (R.sub.2H)                                                                        215 (R.sub.3L)                                                                         49.7                                  ______________________________________                                    

As an example, as shown in Table I, for selected values of attenuation, and the selected value of characteristic impedance Z_(o), the values for R₁, R₂ and R₃ of the equivalent circuit shown in FIG. 2A are calculated for each attenuation state using equations 3, 4 and 5.

Referring now to FIG. 3, the digital attenuator circuit 10 is shown formed as a monolithic circuit on a substrate 30, here of semi-insulating gallium arsenide having on a bottom surface thereof a conductive ground plane 32, here of plated gold. On a surface of substrate 30 opposite the ground plane conductor 32 are formed active regions (not shown) wherein are formed FETS 14a, 14b, 14c (FIG. 1). FETS 14a-14c here each include a plurality of channel regions C_(x) (FIGS. 4A, 5), said channels including gate regions G_(x) disposed between pairs of source (S) and drain (D) regions. Capacitors 12a-12b are conventionally fabricated parallel plate capacitors having a bottom plate (not shown) coupled to the ground plane by via holes 12a', 12b'. Conductive bonding pads 15a, 15b are provided for connection to bias control means 21 (FIG. 1). On the semi-insulating substrate 30 are provided strip conductors 19a'-19d' and 13a'-13c' for respective ones of transmission lines 19a-19d and 13a-13c (FIG. 1). Thus, here microstrip transmission lines are provided by a combination of the aforementioned strip conductors, semi-insulating substrate 30 and ground plane conductor 32. Further, conventional overlay metallizations 19a"-19d" and 19b" are provided to interconnect like ones of drain and source electrodes of each FET 14a-14c, as shown.

Referring now to FIGS. 4 and 4A, FET 14a, also representative of FET 14b, is shown to include a mesa-shaped active region 34a, contact region 36a, a plurality of recesses 35 in contact region 36a exposing underlying portions of active layer 34a, and a plurality of channel regions C₁ -C₁₀ disposed in active region 36a between pairs of drain D and source S electrodes and underlying corresponding ones of gate fingers G₁ -G₁₀. Gate fingers G₁ -G₈ are connected to a gate pad 35a (representative of gate electrode 15a, FIG. 1). Gate pad 35a is connected to the resistor R_(a), and is adapted to receive a control signal from control means 21 at bias point V₁ (FIG. 1). Gate fingers G₉, G₁₀ are connected to gate pad 35a' here spaced from gate pad 35a by a channel 40 provided between said gate pads 35a and 35a'. Further as shown in FIG. 4, gate finger G₈ covers a portion of the active region thereunder between respective drain and source contacts. In this manner, field effect transistor 14a is designed to have a selected value of resistance R_(1H) when a voltage signal is applied to gate pad 35a to pinch-off each of the drain source channel regions C₁ -C₁₀. As is known in the art, when a conventional depletion mode field effect transistor, for example, is supplied with a voltage sufficient to cause pinch-off of the channel, a very high channel impedance, typically in the range of thousands of ohms is provided. Here, in order to provide an attenuator having the desired degree of attenuation values and values of resistance to provide in combination a predetermined input impedance preferably equal to the impedance of the radio frequency transmission lines, the field effect transistor 14a, for example, is designed to have a selected value of channel resistance R_(1L) when the field effect transistor is in the "on state" and a selected value of channel resistance R_(1H) when the field effect transistor is in the pinch-off state. The FET 14a further includes conventional drain and source overlay metallization 19a"-19b" used to interconnect corresponding ones of drain (D) and source (S) electrodes, as shown.

Referring to FIG. 5, FET 14c is here a dual gate FET having gate finger pairs G_(1a), G_(1b), G_(2a), G_(2b), G_(3a), G_(3b) and G_(4a), G_(4b). Resistors R_(c1) -R_(c5) are provided in combination with the pairs of dual gates to increase the isolation between gate and drain electrodes and to increase current limiting and the drain-gate breakdown voltage. Gate pairs G_(1a), G_(1b), G_(2a), G_(2b), G_(3a), G_(3b) and G_(4a), G_(4b) are connected to a gate pad 35c (FIG. 3, representative of gate electrode 15c, FIG. 1) through resistors R_(c1) -R_(c5), as shown. Source electrodes (S) of FET 14c are connected to a source pad 39c which is connected to ground through a via hole 39c'.

In operation, a two level voltage signal having a first level sufficient to pinch-off the channel is fed to gate electrode pad 35a. Such voltage signal is distributed to gate electrode fingers G₁ -G₈ disposed between adjacently spaced source and drain electrodes to pinch-off the corresponding source-drain channels C₁ -C₈ of each one of the corresponding FET cells. Thus, such channels C₁ -C₈ disposed under the connected gate fingers G₁ -G₈ will be placed in a pinch-off state. However, since the pinch-off voltage signal is not fed to the portion of the gate pad 35a' spaced by channel 40 from gate pad 35a, such signal therefore is not distributed to channels C₉, C₁₀ underlying gate fingers G₉, G₁₀. Further, that portion of the channel C₈ isolated from gate finger G₈ is in a like manner not pinched-off. Thus, the source-drain channel underlying gate fingers G₉, G₁₀ will not be placed in a pinch-off state and will present an impedance equal to the "on-state" channel resistance of such channel, and the gate finger G₈ disposed on a portion of the total channel C₉ width will provide a lower channel resistance in the pinch-off state than those channels C₁ -C₈ having a complete gate finger disposed thereon. Since the channels are coupled in parallel, the total resistance of the field effect transistor between the drain electrode 16a and source electrode 17a when a pinch-off voltage level signal is applied to the gate electrode will be selectively lower than conventional field effect transistors wherein all gate fingers G₁ -G₁₀, for example, would be fed a voltage level signal to place each one of the channels thereof in a pinch-off state.

A generalized equation for finding the equivalent resistance (R_(1H)) in pinch-off for the field effect transistor such as that shown in FIG. 4 having n channels, with m channels and portions thereof isolated from the gate pad 35a, having a selected on-state channel resistance equal to R_(o) ohms per channel, and a selected pinch-off channel resistance of R_(p) ohms per channel is given as:

    1/R.sub.1H =m/R.sub.0 +(1/(R.sub.p /(n-m)))                (Equation 6)

As a design example, the FET 14a is selected to have a predetermined resistance gate periphery characteristic. Here, FET's 14a, 14b are each selected to have a resistance-gate periphery characteristic equal to R_(XL) =3.5 ohm-mm in the on-state (state where no pinch-off voltage is applied), and a resistance-width characteristic equal to R_(XH) =2.0 K ohm-mm in the off-state (state where a pinch-off voltage is applied).

Selecting the FET 14a to have 10 cells, then each unit cell will have a unit cell width w_(o) given by w_(o) =1 mm/n=1 mm/10=100 μm. Further, each cell will have a unit cell on-state resistance (r_(o)) given by R_(XL) /w_(o) =3.5 ohm-mm/(100 μm/cell)= 35 ohms and a unit off-state (pinch-off) channel resistance given by R_(XH) /w_(o) =2.0K ohms-mm/100 μm/cell=20 K ohms.

The required gate periphery G_(p) for each of FETS 14a, 14b is determined by the desired value of on-state channel resistance (R_(1L)) in accordance with the following equation R_(XL) /R_(1L) =G_(p) where G_(p) equals the total gate periphery. In the present example, G_(p) is given as:

    G.sub.p =R.sub.XL /R.sub.1L =3.5 ohm-mm/5.7 ohm=0.614 mm.

Having found the required total gate periphery (G_(p)) for FET 14a, such total gate periphery G_(p) is selectively partitioned into the plurality of (n) channels, each channel having a width W_(c) such that nW_(c) =G_(p). In the present example, n=10 as selected above and W_(c) is thus given by:

    W.sub.c =0.614 mm/10=0.0614 mm =61.4 μm.

Knowing unit channel resistance valves r_(o) and r_(p), unit channel width w_(o), and having determined the actual width W_(c) =61.4 μm for each one of the channels C₁ -C₁₀ of FETS 14a, 14b, scaled resistance values per channel (R_(o), R_(p)) for the FETS 14a, 14b having a 3.5 ohm-mm characteristic, with each cell having a width of 61.4 μm, are determined as follows:

    w.sub.o r.sub.o /W.sub.c =R.sub.o =(100 μm)(35 ohms)/61.4 μm=57.0 ohms

    w.sub.o r.sub.p /W.sub.c =R.sub.p =(100 μm)(20K ohms)/61.4μm=32.5K ohms

Thus, having determined R_(1H) from equation 3, the FET resistance in the pinch-off state, and having calculated R_(o) the resistance per channel of FETS 14a, 14b in the on-state and R_(p) the pinch-off resistance per channel of FETS 14a, 14b in the pinch-off state, equation 6 can be solved for m to provide the number of channels required to be isolated from the gate pad 35a to provide the value of FET resistance R_(1H) as determined from equation 3 and given in Table 1. For the above example, solving equation 6 for m provides:

    m=((R.sub.o R.sub.p /R.sub.XH)-R.sub.o n)/(R.sub.p -R.sub.o) or

    for R.sub.p >R.sub.o n

    m≃R.sub.o /R.sub.XH ≃57 ohms/21.5 ohms≃2.65

Therefore, as shown in FIG. 4, gate fingers G₉ and G₁₀ are isolated from gate pads 35a and 0.65×61.4 μm=40 μm of channel C₈ is isolated from gate pad 35a.

In a similar manner, FET 14c is designed. Here due to the relatively high on-state channel impedance R_(1L), the FET 14c channel is selectively doped such that the FET 14c has a resistance-width characteristic R_(XL) =14.0 ohm-mm in the on-state and a resistance-width characteristic equal to R_(XH) =8K ohm-mm in the off-state (64.0 ohms per cell on-state and 32K ohms per cell off-state). The total gate periphery G_(p) is given by G_(p) =R_(XL) /R_(3L) =14 ohm-mm/47 ohms=0.280 mm. Having determined the total gate periphery, the number of cells can be selected to be an integral number, here 4 and the width of each one of said cells is then given as: W_(c) =280 μm/4 cells=75 μm/cell. Thus, in a similar manner, r_(o) =R_(XL) n and r_(p) =R_(XH) n or r_(o) =64 ohms per cell and r_(o) =R_(XL) n and r_(p) =R_(XH) n or r_(o) =64 ohms per cell and r_(p) =32K ohms per cell. Normalized or scaled valves R_(o), R_(p) for 75 μm wide cells are determined for the 75 μm wide cells of FET 14c in accordance with w_(o) (r_(o))/W_(c) =R_(o) or 100 μm(64 ohms)/75 μm=85 ohms and w_(o) r_(o) /W_(c) =R_(p) =100 μm(32K ohms)/75 μm=43.7K ohms. Equation 6 is then solved for m to provide: m≃0.4. Therefore, as shown in FIG. 3, (0.4)(75 μm)=30 μm of channel C₁ of FET 14c is isolated from gate pad 35c.

Having described preferred embodiments of the invention, it will now be apparent to one of skill in the art that other embodiments incorporating its concept may be used. It is felt, therefore, that this invention should not be restricted to the disclosed embodiments, but rather should be limited only by the spirit and scope of the appended claims. 

What is claimed is:
 1. A radio frequency circuit having an input terminal and an output terminal comprising:a pair of field effect transistors, each transistor having drain, source and gate electrodes, with a first one of such drain and source electrodes of a first one of such pair of transistors being electrically coupled to the input terminal, a first one of such drain and source electrodes of a second one of the pair of transistors being electrically coupled to the output terminal, and the remaining one of drain and source electrodes of each one of the pair of transistors being electrically coupled at a common point; a third field effect transistor having a drain, source and gate electrodes with first one of such drain and source electrodes being electrically coupled with the aforementioned pair of transistors at the common point and the remaining one of such drain and source electrodes being electrically coupled to a reference potential; each field effect transistor having at least one pair of drain and source contacts disposed on a corresponding pair of drain and source regions and coupled to respective ones of the drain and source electrodes, and at least one gate contact disposed on a corresponding gate region between said pair of drain and source contacts; and wherein a selected portion of the gate region of each field effect transistor is physically separated from the gate contact having the gate electrode attached thereto.
 2. The radio frequency circuit as recited in claim 1 wherein each gate region physically separated from the gate contact of each field effect transistor is selected to provide a predetermined resistance between corresponding source and drain electrodes in response to a signal fed to the corresponding gate electrode of each field effect transistor.
 3. The radio frequency circuit as recited in claim 2 wherein the predetermined resistance between source and drain electrodes of each field effect transistor is selected to provide, in combination, a predetermined impedance at said input and output terminals.
 4. The radio frequency circuit as recited in claim 3 wherein a first set of voltage level signals is fed to the corresponding gate electrode of each one of the field effect transistors providing a first set of resistance values between drain and source electrodes of each one of such field effect transistors, and in response thereto, an input signal fed to the input terminal of the circuit appears at the output terminal of the circuit having an amplitude related to the first set of resistance values between said source and drain electrodes, and wherein a second different set of voltage level signals is fed to the corresponding gate electrode of each one of the field effect transistors providing a second different set of resistance values between source and drain electrodes, and in response thereto, an input signal fed to the input terminal of the circuit appears at the output terminal of the circuit with a second different amplitude related to the values of the second different set of resistance values between source and drain electrodes. 